C. Turlan

Playing second fiddle: second-strand processing and liberation of transposable elements from donor DNA

Retroviruses and many transposons of both prokaryotes and eukaryotes share similar chemical reactions in their transposition. Some elements remain attached to donor DNA during transposition and their translocation results in a fusion between target and donor replicons. However, many elements are separated from their flanking donor DNA prior to their insertion into a target site, which requires processing of both strands at both ends of the element. A variety of strategies have been adopted for cleavage of the second, complementary strand to liberate the transposon.

Diversity of Tn4001 Transposition Products: the Flanking IS256 Elements Can Form Tandem Dimers and IS Circles

We show that both flanking IS256 elements carried by transposon Tn4001 are capable of generating head-to-tail tandem copies and free circular forms, implying that both are active. Our results suggest that the tandem structures arise from dimeric copies of the donor or vector plasmid present in the population by a mechanism in which an IS256 belonging to one Tn4001 copy attacks an IS256 end carried by the second Tn4001 copy. The resulting structures carry abutted left (inverted left repeat [IRL]) and right (inverted right repeat [IRR]) IS256 ends. Examination of the junction sequence suggested that it may form a relatively good promoter capable of driving transposase synthesis in Escherichia coli. This behavior resembles that of an increasing number of bacterial insertion sequences which generate integrative junctions as part of the transposition cycle. Sequence analysis of the IRL-IRR junctions demonstrated that attack of one end by the other is largely oriented (IRL attacks IRR). Our experiments also defined the functional tips of IS256 as the tips predicted from sequence alignments, confirming that the terminal 4 bp at each end are indeed different. The appearance of these multiple plasmid and transposon forms indicates that care should be exercised when Tn4001 is used in transposition mutagenesis. This is especially true when it is used with naturally transformable hosts, such as Streptococcus pneumoniae, in which reconstitution of the donor plasmid may select for higher-order multimers.

IS911 transpososome assembly as analysed by tethered particle motion

Initiation of transposition requires formation of a synaptic complex between both transposon ends and the transposase (Tpase), the enzyme which catalyses DNA cleavage and strand transfer and which ensures transposon mobility. We have used a single-molecule approach, tethered particle motion (TPM), to observe binding of a Tpase derivative, OrfAB[149], amputated for its C-terminal catalytic domain, to DNA molecules carrying one or two IS911 ends. Binding of OrfAB[149] to a single IS911 end provoked a small shortening of the DNA. This is consistent with a DNA bend introduced by protein binding to a single end. This was confirmed using a classic gel retardation assay with circularly permuted DNA substrates. When two ends were present on the tethered DNA in their natural, inverted, configuration, Tpase not only provoked the short reduction in length but also generated species with greatly reduce effective length consistent with DNA looping between the ends. Once formed, this ‘looped’ species was very stable. Kinetic analysis in real-time suggested that passage from the bound unlooped to the looped state could involve another species of intermediate length in which both transposon ends are bound. DNA carrying directly repeated ends also gave rise to the looped species but the level of the intermediate species was significantly enhanced. Its accumulation could reflect a less favourable synapse formation from this configuration than for the inverted ends. This is compatible with a model in which Tpase binds separately to and bends each end (the intermediate species) and protein–protein interactions then lead to synapsis (the looped species).

Dual role of transcription and transcript stability in the regulation of gene expression in Escherichia coli cells cultured on glucose at different growth rates

Microorganisms extensively reorganize gene expression to adjust growth rate to changes in growth conditions. At the genomic scale, we measured the contribution of both transcription and transcript stability to regulating messenger RNA (mRNA) concentration in Escherichia coli. Transcriptional control was the dominant regulatory process. Between growth rates of 0.10 and 0.63 h−1, there was a generic increase in the bulk mRNA transcription. However, many transcripts became less stable and the median mRNA half-life decreased from 4.2 to 2.8 min. This is the first evidence that mRNA turnover is slower at extremely low-growth rates. The destabilization of many, but not all, transcripts at high-growth rate correlated with transcriptional upregulation of genes encoding the mRNA degradation machinery. We identified five classes of growth-rate regulation ranging from mainly transcriptional to mainly degradational. In general, differential stability within polycistronic messages encoded by operons does not appear to be affected by growth rate. We show here that the substantial reorganization of gene expression involving downregulation of tricarboxylic acid cycle genes and acetyl-CoA synthetase at high-growth rates is controlled mainly by transcript stability. Overall, our results demonstrate that the control of transcript stability has an important role in fine-tuning mRNA concentration during changes in growth rate.

The role of tandem IS dimers in IS911 transposition

Using a combined in vivo and in vitro approach, we demonstrated that the transposition products generated by IS911 from a dimeric donor plasmid are different from those generated from a plasmid monomer. When carried by a monomeric plasmid donor, free IS911 transposon circles are generated by intra‐IS recombination in which one IS end undergoes attack by the other. These represent transposition intermediates that undergo integration using the abutted left (IRL) and right (IRR) ends of the element, the active IRR–IRL junction, to generate simple insertions. In contrast, the two IS911 copies carried by a dimeric donor plasmid not only underwent intra‐IS recombination to generate transposon circles but additionally participated in inter‐IS recombination. This also creates an active IRR–IRL junction by generating a head‐to‐tail IS tandem dimer ([IS]2) in which one of the original plasmid backbone copies is eliminated in the formation of the junction. Both transposon circles and IS tandem dimers are generated from an intermediate in which two transposon ends are retained by a single strand joint to generate a figure 8 molecule. Inter‐IS figure 8 molecules generated in vitro could be resolved into the [IS]2 form following introduction into a host strain by transformation. Resolution did not require IS911 transposase. The [IS]2 structure was stable in the absence of transposase but was highly unstable in its presence both in vivo and in vitro. Previous studies had demonstrated that the IRR–IRL junction promotes efficient intermolecular integration and intramolecular deletions both in vivo and in vitro. Integration of the [IS]2 derivative would result in a product that resembles a co‐integrate structure. It is also shown here that the IRR–IRL junction of the [IS]2 form and derivative structures can specifically target one of the other ends in an intramolecular transposition reaction to generate transposon circles in vitro. These results not only demonstrate that IS911 (and presumably other members of the IS3 family) is capable of generating a range of transposition products, it also provides a mechanistic framework which explains the formation and activity of such structures previously observed for several other unrelated IS elements. This behaviour is probably characteristic of a large number of IS elements.

A target specificity switch in IS911 transposition: the role of the OrfA protein

The role played by insertion sequence IS911 proteins, OrfA and OrfAB, in the choice of a target for insertion was studied. IS911 transposition occurs in several steps: synapsis of the two transposon ends (IRR and IRL); formation of a figure‐of‐eight intermediate where both ends are joined by a single‐strand bridge; resolution into a circular form carrying an IRR–IRL junction; and insertion into a DNA target. In vivo, with OrfAB alone, an IS911‐based transposon integrated with high probability next to an IS911 end located on the target plasmid. OrfA greatly reduced the proportion of these events. This was confirmed in vitro using a transposon with a preformed IRR–IRL junction to examine the final insertion step. Addition of OrfA resulted in a large increase in insertion frequency and greatly increased the proportion of non‐targeted insertions. The intermolecular reaction leading to targeted insertion may resemble the intramolecular reaction involving figure‐of‐eight molecules, which leads to the formation of circles. OrfA could, therefore, be considered as a molecular switch modulating the site‐specific recombination activity of OrfAB and facilitating dispersion of the insertion sequence (IS) to ‘non‐homologous’ target sites.

IS911 transposon circles give rise to linear forms that can undergo integration in vitro

High levels of expression of the transposase OrfAB of bacterial insertion sequence IS911 leads to the formation of excised transposon circles, in which the two abutted ends are separated by 3 bp. Initially, OrfAB catalyses only single‐strand cleavage at one 3′ transposon end and strand transfer of that end to the other. It is believed that this molecule, in which both transposon ends are held together in a single‐strand bridge, is then converted to the circular form by the action of host factors. The transposon circles can be integrated efficiently into an appropriate target in vivo and in vitro in the presence of OrfAB and a second IS911 protein OrfA. In the results reported here, we have identified linear transposon forms in vivo from a transposon present in a plasmid, raising the possibility that IS911 can also transpose using a cut‐and‐paste mechanism. However, the linear species appeared not to be derived directly from the plasmid‐based copy by direct double‐strand cleavages at both ends, but from preformed excised transposon circles. This was confirmed further by the observation that OrfAB can cleave a cloned circle junction both in vivo and in vitro by two single‐strand cleavages at the 3′ transposon ends to generate a linear transposon form with a 3′‐OH and a three‐nucleotide 5′ overhang at the ends. Moreover, while significantly less efficient than the transposon circle, a precleaved linear transposon underwent detectable levels of integration in vitro. The possible role of such molecules in the IS911 transposition pathway is discussed.

Functional domains of the IS1 transposase: analysis in vivo and in vitro

The IS1 bacterial insertion sequence family, considered to be restricted to Enterobacteria, has now been extended to other Eubacteria and to Archaebacteria, reviving interest in its study. To analyse the functional domains of the InsAB′ transposase of IS1A, a representative of this family, we used an in vivo system which measures IS1‐promoted rescue of a temperature‐sensitive pSC101 plasmid by fusion with a pBR322::IS1 derivative. We also describe the partial purification of the IS1 transposase and the development of several in vitro assays for transposase activity. These included a DNA band shift assay, a transposase‐mediated cleavage assay and an integration assay.  Alignments  of  IS  family  members  (http://www‐is.biotoul.fr) not only confirmed the presence of an N‐terminal helix–turn–helix and a C‐terminal DDE motif in InsAB′, but also revealed a putative N‐terminal zinc finger. We have combined the in vitro and in vivo tests to carry out a functional analysis of InsAB′ using a series of site‐directed InsAB′ mutants based on these alignments. The results demonstrate that appropriate mutations in the zinc finger and helix–turn–helix motifs result in loss of binding activity to the ends of IS1 whereas mutations in the DDE domain are affected in subsequent transposition steps but not in end binding.

The Csr system regulates genome-wide mRNA stability and transcription and thus gene expression in Escherichia coli.

Bacterial adaptation requires large-scale regulation of gene expression. We have performed a genome-wide analysis of the Csr system, which regulates many important cellular functions. The Csr system is involved in post-transcriptional regulation, but a role in transcriptional regulation has also been suggested. Two proteins, an RNA-binding protein CsrA and an atypical signaling protein CsrD, participate in the Csr system. Genome-wide transcript stabilities and levels were compared in wildtype E. coli (MG1655) and isogenic mutant strains deficient in CsrA or CsrD activity demonstrating for the first time that CsrA and CsrD are global negative and positive regulators of transcription, respectively. The role of CsrA in transcription regulation may be indirect due to the 4.6-fold increase in csrD mRNA concentration in the CsrA deficient strain. Transcriptional action of CsrA and CsrD on a few genes was validated by transcriptional fusions. In addition to an effect on transcription, CsrA stabilizes thousands of mRNAs. This is the first demonstration that CsrA is a global positive regulator of mRNA stability. For one hundred genes, we predict that direct control of mRNA stability by CsrA might contribute to metabolic adaptation by regulating expression of genes involved in carbon metabolism and transport independently of transcriptional regulation.

IS911 partial transposition products and their processing by the Escherichia coli RecG helicase

Insertion of bacterial insertion sequence IS911 can often be directed to sequences resembling its ends. We have investigated this type of transposition and shown that it can occur via cleavage of a single end and its targeted transfer next to another end. The single end transfer (SET) events generate branched DNA molecules that contain a nicked Holliday junction and can be considered as partial transposition products. Our results indicate that these can be processed by the Escherichia coli host independently of IS911‐encoded proteins. Such resolution depends on the presence of homologous DNA regions neighbouring the cross‐over point in the SET molecule. Processing is often accompanied by sequence conversion between donor and target sequences, suggesting that branch migration is involved. We show that resolution is greatly reduced in a recG host. Thus, the branched DNA‐specific helicase, RecG, involved in processing of potentially lethal DNA structures such as stalled replication forks, also intervenes in the resolution of partial IS911 transposition products.